JP7493284B2 - Manhole rehabilitation construction method - Google Patents

Description

The present invention relates to a method for constructing a manhole rehabilitation structure, and in particular to a method for constructing a manhole rehabilitation structure in which a cylindrical rehabilitation manhole is installed inside an existing buried manhole.

The average sewerage coverage rate in Japan is about 79%, and in urban areas, it is close to 100%. Sewer pipes deteriorate with years of use, and their useful life is generally considered to be about 50 years. The total length of sewer pipes is over 470,000 km, and the number of manholes associated with it is about 8 to 10 million. In recent years, the number of manholes that have exceeded their useful life has been increasing, and repairs due to deterioration are urgently needed. Generally, manholes are installed in the ground as cylindrical bodies of a certain thickness, with the top of the cylinder opening at the ground surface.

A method using backfill material is generally known as a method for rehabilitating such manholes. In this method, as described in Patent Document 1, a cylindrical repair material is assembled along the inner circumferential surface of an existing cylindrical manhole, and a spacer is placed between the outer circumferential surface of the repair material and the inner circumferential surface of the existing manhole to form a gap. A backfill material such as mortar is injected into this gap and allowed to harden, thereby integrating the existing manhole with a rehabilitating manhole made up of the backfill material and repair material.

Patent Document 2 also describes another construction method that does not use a backfill material, but uses a lining material in which a photocurable resin composition is impregnated into a glass fiber substrate. In this construction method, first, a cylindrical uncured lining material with an opening sealed by a sealing device is introduced in a folded state into the interior of an existing manhole. Air is then introduced into the interior of the lining material from the air inlet of the sealing device to expand it, and the lining material is pressed against the inner wall of the existing manhole. In this state, light is irradiated from a light irradiation device that has been previously introduced into the interior of the bag-shaped lining material, and the photocured lining material, i.e., the rehabilitation manhole, is integrated with the existing manhole.

Manhole rehabilitation structures that use lining materials generally have the advantage that the hardened lining material alone can ensure the manhole's ability to withstand vertical loads, since the hardened lining material is generally stronger than the backfill material.

JP 2001-090173 A JP 2014-076592 A

Vertical loads acting from above on the lid that covers the top opening of a manhole, such as vertical loads received from people or vehicles passing over the manhole, act on the upper end surface of the manhole via a lid receiving frame that is provided at the top of the manhole to secure the lid to the manhole, and an annular adjustment ring that is installed as necessary to adjust the height of the manhole.

Generally, the inner diameter of the lid receiving frame and adjustment ring is set to the same size as the inner diameter of the standardized upper opening of an existing manhole, and when a new rehabilitation manhole is installed inside an existing manhole, the outer diameter of the rehabilitation manhole will be smaller than the inner diameter of the existing lid receiving frame and the inner diameter of the existing adjustment ring.

Therefore, if the existing lid receiving frame and adjustment ring were used, the vertical load acting on the lid would not be transmitted to the rehabilitated manhole, and the load-bearing capacity of the newly constructed rehabilitated manhole could not be fully utilized, which was a problem.

The present invention was made in consideration of the above problems, and aims to provide a method for constructing a manhole rehabilitation structure in which a cylindrical rehabilitation manhole is installed inside an existing manhole, and in which a vertical load acting on the cover from above can be transmitted to the rehabilitation manhole.

In order to achieve the above object, a construction method for a manhole rehabilitation structure according to claim 1 of the present invention comprises the steps of:
A method for constructing a manhole rehabilitation structure, comprising the steps of: installing a cylindrical rehabilitation manhole of a predetermined thickness inside an existing manhole that is buried underground and has a cylindrical straight wall portion and an inclined wall portion that is installed above the straight wall portion and has an inner diameter and an outer diameter that gradually decrease toward the top;
a rehabilitation manhole installation process for installing the rehabilitation manhole inside the existing manhole in a state where the rehabilitation manhole is in close contact with the straight wall portion and the inclined wall portion and such that the upper end surface of the rehabilitation manhole is at a height equal to or higher than the upper end surface of the inclined wall portion;
a load transmission member installation process for installing an annular load transmission member so as to overlap an upper end surface of the inclined wall portion of the existing manhole and an upper end surface of the rehabilitation manhole;
a lid installation process for installing a lid that closes an upper opening of the existing manhole via a lid receiving frame having an inner diameter that is approximately the same as the inner diameter of the upper end surface of the inclined wall portion of the existing manhole;
The present invention is characterized by comprising:

According to this configuration, by placing a cover of a size for the existing manhole on the load transmission member, the vertical load acting from above the cover is transmitted from the cover to the load transmission member and then to the upper end face of the rehabilitation manhole below this load transmission member. As a result, even if the existing manhole can no longer withstand the required vertical load due to deterioration, the vertical load received from above the cover can be transmitted to the rehabilitation manhole, making full use of the load-bearing capacity of the newly installed rehabilitation manhole and maintaining the performance of the manhole.

In addition, a construction method for a manhole rehabilitation structure according to claim 2 of the present invention is the construction method for a manhole rehabilitation structure according to claim 1,
The load transmitting member is
An annular body portion;
It is characterized by having a protrusion that protrudes downward from the lower surface of the main body and directly or indirectly abuts against the inner surface of the rehabilitation manhole.

With this configuration, the protruding portion of the load transmission member and the inner peripheral surface of the rehabilitation manhole come into contact with each other, preventing the load transmission member from shifting out of position relative to the rehabilitation manhole. This prevents the load transmission member from shifting out of position from its initial position due to long-term use, which would otherwise cause a decrease in the load transmission function to the rehabilitation manhole.

In addition, a construction method for a manhole rehabilitation structure according to claim 3 of the present invention is the construction method for a manhole rehabilitation structure according to claim 1 or 2,
A ring-shaped height adjustment member is placed on the upper end surface of the existing manhole,
In the rehabilitation manhole installation process, the upper end surface of the rehabilitation manhole is formed so as to be flush with the upper end surface of the existing manhole or the upper end surface of the height adjustment member.

According to this configuration, by placing a load transmission member on the rehabilitating manhole, which has a flush upper end surface, and the existing manhole or the height adjustment member, the force acting on the cover can be applied from the load transmission member to the rehabilitating manhole and the existing manhole. In other words, if the load-bearing capacity of the existing manhole is maintained, the upper end surface of the rehabilitating manhole can be made flush with the upper end surface of the existing manhole or the height adjustment member placed on it, and both the existing manhole and the rehabilitating manhole can receive a vertical load, improving the load-bearing capacity of the entire manhole.

In addition, a construction method for a manhole rehabilitation structure according to claim 4 of the present invention is the construction method for a manhole rehabilitation structure according to claim 1 or 2,
The load transmitting member includes a locking portion protruding from an upper surface of a ring-shaped main body portion,
After the load transmission member is installed, an annular height adjustment member whose inner surface abuts the engaging portion is installed on the load transmission member, and the lid receiving frame and the lid are placed on the height adjustment member.

With this configuration, the locking portion of the load transmission member can be abutted against the inner peripheral surface of the height adjustment member placed on the load transmission member, preventing the relative positional shift between the load transmission member and the height adjustment member. This prevents the relative positional shift between the height adjustment member and the load transmission member caused by long-term use from occurring, which would result in a decrease in the load transmission function to the rehabilitation manhole.

A method for constructing a manhole rehabilitation structure according to claim 5 of the present invention is the method for constructing a manhole rehabilitation structure according to claim 1 or 2,
The rehabilitation manhole is composed of a fiber base material and a cured product of a photocurable resin composition, and is characterized by having a strength capable of withstanding a predetermined vertical load by itself.

With this configuration, even if the existing manhole is damaged due to deterioration, the vertical load received by the cover is transmitted to the rehabilitation manhole by the load transmission member, and the rehabilitation manhole can maintain its performance by itself.

According to the construction method of the manhole rehabilitation structure of the present invention, when a vertical load acts on the cover from above in the constructed manhole rehabilitation structure, this vertical load can be transmitted to the upper end surface of the rehabilitation manhole below the load transmission member. This allows the vertical load acting on the cover to be transmitted to the rehabilitation manhole, making full use of the load-bearing capacity of the newly constructed rehabilitation manhole, and allowing the performance of the manhole to be maintained even if the existing manhole can no longer withstand the required vertical load due to aging.

1 is a cross-sectional view showing a schematic diagram of a manhole rehabilitation structure according to a first embodiment of the construction method of the present invention. FIG. An enlarged cross-sectional view of a key portion of a manhole rehabilitation structure. FIG. 3 is a diagram showing another example of an installation state of the load transmitting member, and is an enlarged cross-sectional view of the area surrounded by X in FIG. 2 . FIG. FIG. 13 is a perspective view showing a modified example of the load transmitting member. FIG. 4 is an enlarged cross-sectional view of a main portion of a manhole rehabilitation structure according to a second embodiment of the construction method of the present invention. FIG. 7 is a perspective view of the load transmitting member shown in FIG. 6 .

First Embodiment
Fig. 1 is a cross-sectional view showing a manhole rehabilitation structure according to a first embodiment of the construction method of the present invention, and Fig. 2 is an enlarged cross-sectional view of a main part of the rehabilitation structure shown in Fig. 1. The drawings used to explain the present invention emphasize the main parts and do not show the actual dimensional ratio. The manhole rehabilitation structure 10 includes an existing manhole 20 buried in the ground to be rehabilitated, a rehabilitation lining material 12 which is a rehabilitation manhole for rehabilitating the existing manhole 20, an adjustment ring 14 and an adjustment mortar 15 which are height adjustment members for adjusting the height of the manhole, a cover 16, and a cover receiving frame 18 (hereinafter simply referred to as the "receiving frame 18"), and a load transmission member 30 between the receiving frame 18 and the rehabilitation lining material 12.

The existing manhole 20 is formed in a cylindrical shape with a bottom having a predetermined thickness. Such existing manholes 20 are arranged at a fixed interval with respect to the sewer pipes buried in the ground, and are attached with the ends of the sewer pipes 51, 52 inserted into the mounting holes 24, 25 formed in the lower wall surface of the existing manhole 20. The upper opening of the existing manhole 20 is usually set to a diameter of 600 mm so that a person can enter. The existing manhole 20 of this embodiment is made of concrete, for example, and has a base 17 that serves as a foundation, an invert part 11 that is installed on the base 17 and forms the bottom surface of the manhole and has a U-shaped groove, a straight wall part 21 that extends cylindrically upward (toward the ground), and an inclined wall part 22 that is located above the straight wall part 21 and has a wall surface that is inclined so that the inner diameter and outer diameter gradually decrease upward.

The rehabilitation lining material 12 is installed inside the existing manhole 20, has a predetermined thickness, and is formed into a bottomed or bottomless cylindrical shape that conforms to the shape of the existing manhole 20. In this embodiment of the rehabilitation lining material 12, the rehabilitation lining material 12 is bottomless cylindrical and has a straight wall cylindrical portion 13A and a slant wall cylindrical portion 13B that are adapted to the straight wall portion 21 and the slant wall portion 22, respectively, of the existing manhole 20, and the straight wall cylindrical portion 13A has sewer pipe mounting holes 28, 29 formed therein that are adapted to the mounting holes 24, 25 of the existing manhole 20.

In this embodiment, the position of the upper end of the rehabilitation lining material 12 coincides with the position of the upper end of the existing manhole 20 in the vertical direction, and the upper end surface 12a of the rehabilitation lining material 12 and the upper end surface 20a of the existing manhole 20 are formed to be approximately flush with each other.

As the material for the rehabilitation lining material 12, for example, an impregnated base material made of fibers or the like (for example, a fiber base material such as glass fiber or polyester fiber, or a nonwoven fabric such as felt) impregnated with a photocurable resin composition and/or a thermosetting resin composition can be used. In this embodiment, an impregnated base material made of glass fiber is impregnated with a photocurable resin composition. The photocurable resin composition can contain, for example, a polymerizable resin, a polymerizable unsaturated monomer, and a photopolymerization initiator, and the polymerizable resin can be an unsaturated polyester, vinyl ester resin, or the like. As the photopolymerization initiator, for example, an ultraviolet polymerization initiator that promotes the polymerization of the resin by ultraviolet light can be used, but it is preferable to use one that can promote the polymerization of the resin by the action of both ultraviolet light and visible light. Such a rehabilitation lining material 12 has flexibility in an uncured state in which the hardening resin composition is not cured, and is formed into a bottomed or bottomless cylindrical shape that is adapted to the shape of the existing manhole 20 so that it has an outer diameter corresponding to the inner diameter of the existing manhole 20 after curing.

The rehabilitation lining material 12 can also be configured to include an inner film and an outer film that protect the inner and outer surfaces, respectively. The inner film is transparent to light from a light irradiation device that irradiates light onto the rehabilitation lining material 12, and it is preferable to use a light-shielding film for the outer film so that the light irradiated from the light irradiation device does not penetrate to the outside of the rehabilitation lining material 12 and is used for the photocuring reaction.

The rehabilitation lining material 12 of this embodiment has a self-supporting structure that can withstand a predetermined vertical load (e.g., a vertical load of 20 tons or more) by itself, without relying on the existing manhole 20. The thickness of the rehabilitation lining material 12 can be 5 mm to 30 mm, and more preferably in the range of 10 mm to 20 mm. This thickness can be set appropriately depending on the inner diameter of the existing manhole 20 to be rehabilitated, etc.

The adjustment ring 14 and the adjustment mortar 15 are members placed on the existing manhole 20 to adjust the height of the existing manhole 20 relative to the ground G and the receiving frame 18, and are formed in a circular ring shape when viewed from above. The adjustment ring 14 is made of concrete, for example, and is placed on the existing manhole 20 via the load transmission member 30. The adjustment mortar 15 is provided on the adjustment ring 14 and is formed by filling the gap between the adjustment ring 14 and the receiving frame 18 with mortar in a ring shape. The thickness of the adjustment ring 14 (i.e., the height in the vertical direction when installed) is greater than the thickness of the adjustment mortar 15. Note that multiple adjustment rings 14 can be installed depending on the required height. The inner and outer diameters of the adjustment ring 14 and the adjustment mortar 15 are approximately the same as the inner and outer diameters of the upper end surface 20a of the existing manhole 20, respectively.

The receiving frame 18 has a ring-shaped installation section 18A and a lid housing section 18B formed at the upper opening edge of the installation section 18A, in which the lid 16 is housed. The installation section 18A is a section that is placed on the upper end surface 20a of the existing manhole 20, and in this embodiment, is installed on the existing manhole 20 via the load transmission member 30, the adjustment ring 14, and the adjustment mortar 15.

The cover 16 is attached to the existing manhole 20 via a receiving frame 18 and closes the upper opening of the existing manhole 20. It is formed in a disk shape.

The load transmission member 30 transmits the external force acting on the cover 16, specifically, the vertical load acting on the cover 16 from above, to the rehabilitation lining material 12, and is an annular member superimposed on both the upper end surface 20a of the existing manhole 20 and the upper end surface 12a of the rehabilitation lining material 12 so that the vertical load transmitted through the cover 16 is transmitted to at least the upper end surface 12a of the rehabilitation lining material 12. The load transmission member 30 can be made of iron, such as cast iron or steel, other metals, or resin, such as fiber-reinforced resin.

As shown in FIG. 3, the load transmission member 30 of this embodiment has an annular main body 32, a protruding portion 36 protruding from the lower surface 32b of the main body 32 (i.e., the surface facing downward when installed), and a locking portion 38 protruding from the upper surface 32a of the main body 32 (i.e., the surface facing upward when installed). The thickness of the main body 32 can be, for example, 5 mm to 25 mm, and preferably 5 mm to 15 mm.

The outer diameter D1 of the main body 32 is set to be larger than the inner diameter of the upper end of the existing manhole 20, and the inner diameter D2 of the main body 32 is set to be smaller than the outer diameter of the upper end of the rehabilitation lining material 12. In this embodiment, the outer diameter D1 of the main body 32 is set to be larger than the inner diameter of the upper end of the existing manhole 20 and smaller than the outer diameter, and the inner diameter D2 of the main body 32 is set to be smaller than the inner diameter of the upper end of the rehabilitation lining material 12. In this embodiment, the thickness of the main body 32 is smaller than the thickness of the adjustment mortar 15. When installed, the main body 32 is arranged concentrically with the upper opening of the existing manhole 20 when viewed from above.

The protrusion 36 is intended to increase the rigidity of the load transmission member 30 and prevent the load transmission member 30 from being displaced relative to the rehabilitation lining material 12. In this embodiment, the protrusion 36 is formed in a cylindrical shape that protrudes vertically from the inner peripheral edge of the lower surface 32b of the main body 32. The outer diameter φ of the protrusion 36 is preferably set to correspond to the inner diameter of the upper end of the rehabilitation lining material 12, and in the example shown in FIG. 2, the outer diameter φ of the protrusion 36 is set to be approximately the same as the inner diameter of the upper end of the rehabilitation lining material 12 so that the outer peripheral surface 37 abuts against the inner peripheral surface 12b of the upper end of the rehabilitation lining material 12 over the circumferential direction in the installed state. In this way, by providing the protrusion 36 that directly abuts against the inner peripheral surface 12b of the rehabilitation lining material 12 on the load transmission member 30, deformation of the load transmission member 30 can be suppressed and the rigidity of the load transmission member 30 can be increased.

Figure 4 is a diagram showing another example of the installation state of the load transmission member 30, and is an enlarged cross-sectional view of the area surrounded by X in Figure 2. In Figure 4, there is a gap between the outer peripheral surface 37 of the protruding portion 36 of the load transmission member 30 and the inner peripheral surface 12b of the rehabilitation lining material 12, and this gap is filled with adhesive 45. For example, an epoxy resin adhesive or a sealant can be used as the adhesive 45. In this way, even if the outer peripheral surface 37 of the protruding portion 36 and the inner peripheral surface 12b of the rehabilitation lining material 12 are indirectly abutted against each other via the adhesive 45, the deformation of the load transmission member 30 can be suppressed and the rigidity of the load transmission member 30 can be increased. The thickness of the rehabilitation lining material 12 can be easily adjusted to match the existing manhole 20 to be repaired during manufacturing, but the load transmission member 30 is generally manufactured using a mold, and changing the shape such as the thickness is costly. Therefore, for example, when a gap is formed between the rehabilitation lining material 12 and the protruding portion 36 of the load transmission member 30 during construction, the gap can be filled with adhesive 45 or the like, as shown in FIG. 4, making the lining material highly versatile. Furthermore, in the example shown in FIG. 4, the adhesive 45 covers the lower surface of the protruding portion 36, and has an inclined portion 45a that extends obliquely from the inner edge of the lower surface toward the inner surface 12b of the rehabilitation lining material 12. In this way, by providing the inclined portion 45a, the effect of suppressing deformation of the main body portion 32 and the protruding portion 36 can be enhanced, and the load transmission performance can be improved.

The shape of the protrusion 36 is not limited to a cylindrical shape, and may be such that multiple protrusions 36 are arranged at intervals in the circumferential direction, as in the locking portion 38 shown in FIG. 3. However, as in this embodiment, the protrusion 36 is formed cylindrically so that the entire circumferential area abuts against the inner surface 12b of the rehabilitation lining material 12, thereby further increasing the rigidity of the entire load transmission member 30.

The locking portions 38 come into contact with the inner peripheral surface of the adjustment ring 14 that is placed on the load transmission member 30, suppressing relative positional deviation between the load transmission member 30 and the adjustment ring 14. In this embodiment, four locking portions 38-1 to 38-4 are provided at intervals in the circumferential direction on the upper surface 32a of the main body portion 32. The size and shape of each locking portion 38 are set so that its outer peripheral surface 39 comes into contact with the inner peripheral surface of the adjustment ring 14 when installed, and in this embodiment, it is formed in an arc shape that follows the inner peripheral surface of the adjustment ring 14.

The number of locking portions 38 is not limited to four, and one or more may be arranged so as to suppress misalignment of the adjustment ring 14, and the shape is not limited to an arc shape. For example, as shown in FIG. 5, when there is one locking portion 38, it may be formed in a cylindrical shape. When there are two or more locking portions 38, it is preferable that they are arranged at approximately equal intervals in the circumferential direction. Furthermore, in the illustrated example, the outer peripheral surface 39 of the locking portion 38 directly contacts the adjustment ring 14, but when a gap is formed between the outer peripheral surface 39 and the inner peripheral surface of the adjustment ring 14, the locking portion 39 may be indirectly contacted with the inner peripheral surface of the adjustment ring 14 via a filler such as an adhesive that fills the gap.

Next, we will explain the construction procedure for the manhole rehabilitation structure 10 equipped with the load transmission member 30.

First, the rehabilitation lining material 12 is installed inside the existing manhole 20. The rehabilitation lining material 12 is installed in the following procedure. First, the cover body 16, the receiving frame 18, the adjustment mortar 15, and the adjustment ring 14 are removed from the existing manhole 20, and the invert part 11 is removed. Then, the unhardened cylindrical rehabilitation lining material 12 is introduced into the existing manhole 20. At this time, the upper and lower openings of the rehabilitation lining material 12 are blocked by upper and lower packers, and the rehabilitation lining material 12 is introduced into the existing manhole 20 using a crane while being suspended by a wire rope attached to the upper packer. Next, compressed air is supplied to the inside of the rehabilitation lining material 12 using a compressor. The compressed air is supplied to the inside of the rehabilitation lining material 12 through an air supply pipe whose one end is connected to the compressor, which penetrates the upper packer and whose other end extends into the rehabilitation lining material 12. After the rehabilitation lining material 12 is expanded and enlarged in the existing manhole 20 by compressed air, a light irradiation device is introduced into the rehabilitation lining material 12 from the device introduction part formed in the upper packer. Then, compressed air is supplied into the rehabilitation lining material 12 by a compressor, and the outer peripheral surface of the rehabilitation lining material 12 is brought into close contact with the inner wall surface of the existing manhole 20. The introduced light irradiation device irradiates light into the rehabilitation lining material 12, hardening the rehabilitation lining material 12. Then, the light irradiation device is removed, and pipe opening processing is performed on the hardened rehabilitation lining material 12 to form water pipe mounting holes 28, 29, an upper opening, and a lower opening.

After the rehabilitation lining material 12 is installed, the invert portion 11 is newly installed at the bottom of the rehabilitation lining material 12. Then, the load transmission member 30 is placed on the upper end surfaces 20a, 12a of the existing manhole 20 and the rehabilitation lining material 12, and the adjustment ring 14, adjustment mortar 15, and receiving frame 18 are placed on top of it in order. Note that adhesive may be applied to the upper end surface 12a of the rehabilitation lining material 12, and the load transmission member 30 may be placed on top of it. By applying adhesive to the upper end surface 12a, the placement surface of the load transmission member 30 can be made flat, the adhesion between the rehabilitation lining material 12 and the load transmission member 30 can be improved, and water leakage from gaps can be prevented, thereby improving the installation stability of the load transmission member 30. The load transmission member 30, the adjustment ring 14, the adjustment mortar 15, and the receiving frame 18 are arranged coaxially with the circular upper opening of the existing manhole 20 in a top view so that the center of the circle coincides with the circular upper opening of the existing manhole 20. The adjustment ring 14, the adjustment mortar 15, and the receiving frame 18 each have a bolt through hole formed therein, and an anchor bolt 40 is inserted through this bolt through hole and a bolt hole formed in the upper end surface 20a of the existing manhole 20, and is fixed by a nut member (not shown).

The load transmission member 30 is fixed to the existing manhole 20 in a state where it is sandwiched between the existing manhole 20 and the adjustment ring 14 in the vertical direction. Although not shown, the outer diameter of the main body 32 of the load transmission member 30 may be increased so that the anchor bolt 40 penetrates the main body 32. In the installed state, the protrusion 36 of the load transmission member 30 protrudes downward from the inner peripheral edge of the main body 32 and abuts against the inner peripheral surface 12b of the rehabilitation lining material 12, and the engagement portion 38 protrudes upward from the main body 32 and abuts against the inner peripheral surface of the adjustment ring 14. The cover 16 is attached to the existing manhole 20 via the load transmission member 30, the adjustment ring 14, the adjustment mortar 15, and the receiving frame 18, and closes the upper opening of the adjustment mortar 15 that is continuous with the upper opening of the existing manhole 20.

Next, we will explain the operation of the manhole rehabilitation structure 10 described above.

In the manhole rehabilitation structure 10, when a vertical load F is applied from above to the cover 16 by a person or vehicle passing over the cover 16, the vertical load F is transmitted to the load transmission member 30 via the receiving frame 18, the adjustment mortar 15, and the adjustment ring 15, and is further transmitted to the upper end surface 20a of the existing manhole 20 and the upper end surface 12a of the rehabilitation lining material 12, which are in contact with the main body 32 of the load transmission member 30, via the load transmission member 30. In this way, by providing the load transmission member 30, the manhole rehabilitation structure 10 is able to transmit the vertical load F acting on the cover 16 to the rehabilitation lining material 12, and as a result, even if the existing manhole 20 can no longer withstand the required vertical load due to aging, the load-bearing performance of the newly installed rehabilitation lining material 12 can be fully utilized to maintain the performance of the manhole. Furthermore, if the load-bearing capacity of the existing manhole 29 is maintained, both the existing manhole 20 and the rehabilitation lining material 12 can bear the vertical load, improving the load-bearing capacity of the entire manhole.

In particular, in this embodiment, the main body 32 of the load transmission member 30, when viewed from above, has its inner peripheral edge located inside the outer peripheral edge of the rehabilitation lining material 12 all around, and its outer peripheral edge located outside the inner peripheral edge of the existing manhole 20 all around. In other words, the main body 32 overlaps vertically with the upper end surface 20a of the existing manhole 20 and the upper end surface 12a of the rehabilitation lining material 12 all around, so that the vertical load F received from the cover 16 can be applied directly to the entire circumference of the existing manhole 20 and the entire circumference of the rehabilitation lining material 12, and the load-bearing performance of the rehabilitation lining material 12 can be effectively utilized.

In addition, the outer peripheral surface 37 of the protrusion 36 on the load transmission member 30 abuts against the inner peripheral surface 12b of the upper end of the rehabilitation lining material 12, preventing the load transmission member 30 from shifting out of position relative to the rehabilitation lining material 12. This prevents the load transmission member 30 from shifting out of position from its initial position due to long-term use, which in turn prevents a decrease in the load transmission function to the rehabilitation lining material 12.

Furthermore, the load transmission member 30 is provided with an engagement portion 38, which abuts against the adjustment ring 14 to prevent the relative positions of the load transmission member 30 and the adjustment ring 14 from shifting. This prevents the positions of the adjustment ring 14 and the load transmission member 30 from shifting due to long-term use, which in turn prevents a decrease in the load transmission function to the rehabilitation lining material 12.

In addition, the rehabilitation lining material 12 of this embodiment has a self-supporting structure that can withstand a predetermined vertical load by itself, without relying on the existing manhole 20, so that the manhole can maintain its functionality even if the existing manhole 20 is damaged due to aging. In particular, by installing the load transmission member 30, it is possible for the rehabilitation lining material 12 alone to withstand the vertical load received by the cover body 16, via the adjustment mortar 15, adjustment ring 14, and load transmission member 30, without relying on the existing manhole 20.

In the above embodiment, the rehabilitation lining material 12 containing a photocurable resin composition is used as a rehabilitation member (hereinafter also referred to as a "rehabilitation manhole") for rehabilitating the existing manhole 20. However, the rehabilitation manhole is not limited to this, and may be composed of, for example, a cylindrical repair material installed with a gap inside the existing manhole 20, and a backfill material filled in the gap between the repair material and the existing manhole 20. A rehabilitation manhole using a backfill material is generally not a freestanding structure that does not depend on the existing manhole 20, but has a composite structure that is integrated with the existing manhole 20 to stiffen the existing manhole 20. Even if the load transmission member 30 is not arranged, it can indirectly support a vertical load via the existing manhole 20, but by interposing the load transmission member 30, it is possible to apply a vertical load directly to the rehabilitation member.

In this way, the manhole rehabilitation structure according to the present invention may use a backfill material as the manhole to be rehabilitated, but by using the rehabilitation lining material 12 of this embodiment, it is possible to make the structure thinner than one that uses a backfill material, while still having high strength and able to withstand the required load. For example, if the thickness of the existing manhole 20 is 100 mm, the thickness of the rehabilitated manhole using the backfill material will be 70 to 80 mm, but if the rehabilitation lining material 12 is used, the thickness can be reduced to 10 to 17 mm, making it possible to make a self-supporting structure that can withstand the required load without relying on the existing manhole 20.

Second Embodiment
Next, a second embodiment of the manhole rehabilitation structure 10 will be described with reference to Figures 6 and 7. Figure 6 is an enlarged cross-sectional view similar to Figure 2, which shows the second embodiment of the manhole rehabilitation structure 10, and the same reference numerals are used to designate parts corresponding to those in the first embodiment. In the second embodiment described below, detailed descriptions of the same configurations as those in the first embodiment will be omitted.

In this embodiment, the load transmission member 30 is interposed between the receiving frame 18 and the adjustment mortar 15, which is a height adjustment member. In addition, the upper end of the rehabilitation lining material 12 extends up to the position of the upper end of the adjustment mortar 15 in the vertical direction, and the upper end surface 12a of the rehabilitation lining material 12 and the upper surface 15a of the adjustment mortar 15 are formed flush with each other.

As shown in FIG. 7, the load transmission member 30 has a protruding portion 36 that protrudes from the lower surface 32b of the main body portion 32, and does not have a locking portion 38. The protruding portion 36 abuts against the inner peripheral surface of the rehabilitation lining material 12 in the installed state, thereby preventing the load transmission member 30 from shifting in position relative to the rehabilitation lining material 12.

In the manhole rehabilitation structure 10 of this embodiment, the vertical load acting on the cover 16 can be transmitted to the upper end surface 12a of the rehabilitation lining material 12 and the upper surface 15a of the adjustment mortar 15 via the receiving frame 18 and the load transmission member 30, and the load-bearing performance of the newly installed rehabilitation lining material 12 can be fully utilized. For example, if the adjustment ring 14 and adjustment mortar 15 can be reused without removing them from the existing manhole 20, it is possible to install the rehabilitation lining material 12 up to the upper end position of the adjustment mortar 15 and place the load transmission member 30 on top of it, as in this embodiment.

Although not shown, the load transmission member 30 may be configured to be placed between the adjustment ring 14 and the adjustment mortar 15, instead of the load transmission member 30 in the first and second embodiments described above. In such a case, the upper end position of the rehabilitation lining material 12 can be configured to coincide with the upper end position of the adjustment ring 14. The main body 32 of the load transmission member 30 is placed on the upper end surface 12a of the rehabilitation lining material 12 and the upper surface of the adjustment ring 14, which are formed flush with each other.

The present invention is not limited to the above-described embodiment, and various modifications are possible without departing from the spirit of the invention.

For example, the load transmission member 30 may have only the main body 32, and may not have the protrusion 36 and the locking portion 38. In such a case, it is possible to prevent the relative positional deviation of the existing manhole 20, the load transmission member 30, and the adjustment ring 14 by providing a through hole in the main body 32 through which the anchor bolt 40 passes and fixing the existing manhole 20, the load transmission member 30, and the adjustment ring 14 with the anchor bolt 40. Furthermore, the load transmission member 30 may have the main body 32 and the locking portion 38, and may not have the protrusion 36.

10 Manhole rehabilitation structure 12 Rehabilitation lining material (rehabilitation manhole)
[0033] 12a Upper end surface of rehabilitation lining material 14, 15 Adjustment ring 16 Lid 18 Receiving frame 20 Existing manhole 20a Upper end surface of existing manhole 30 Load transmission member 32 Main body 32a Upper surface of main body 32b Lower surface of main body 36 Protruding portion 37 Outer peripheral surface of protruding portion 38 Locking portion 39 Outer peripheral surface of locking portion 40 Anchor bolt

Claims (5)

A method for constructing a manhole rehabilitation structure, comprising the steps of: installing a cylindrical rehabilitation manhole of a predetermined thickness inside an existing manhole that is buried underground and has a cylindrical straight wall portion and an inclined wall portion that is installed above the straight wall portion and has an inner diameter and an outer diameter that gradually decrease toward the top;
a rehabilitation manhole installation process for installing the rehabilitation manhole inside the existing manhole in a state where the rehabilitation manhole is in close contact with the straight wall portion and the inclined wall portion and such that the upper end surface of the rehabilitation manhole is at a height equal to or higher than the upper end surface of the inclined wall portion;
a load transmission member installation process for installing an annular load transmission member so as to overlap an upper end surface of the inclined wall portion of the existing manhole and an upper end surface of the rehabilitation manhole;
a cover installation process for installing a cover that closes an upper opening of the existing manhole via a cover receiving frame having an inner diameter that is approximately the same as the inner diameter of the upper end surface of the inclined wall portion of the existing manhole;
A construction method for a manhole rehabilitation structure, comprising: The load transmitting member is
An annular body portion;
A construction method for a manhole rehabilitation structure as described in claim 1, characterized in that it has a protrusion that protrudes downward from the underside of the main body and directly or indirectly abuts the inner surface of the rehabilitation manhole. A ring-shaped height adjustment member is placed on the upper end surface of the existing manhole,
A construction method for a manhole rehabilitation structure as described in claim 1 or 2, characterized in that in the rehabilitation manhole installation process, the upper end surface of the rehabilitation manhole is formed so as to be flush with the upper end surface of the existing manhole or the upper end surface of the height adjustment member. The load transmitting member includes a locking portion protruding from an upper surface of a ring-shaped main body portion,
A construction method for a manhole rehabilitation structure as described in claim 1 or 2, characterized in that after installing the load transmission member, an annular height adjustment member whose inner surface abuts the engaging portion is installed on the load transmission member, and the lid body receiving frame and the lid body are placed on the height adjustment member. The construction method for a manhole rehabilitation structure according to claim 1 or 2, characterized in that the manhole for rehabilitation is made of a fiber base material and a cured product of a photocurable resin composition, and has a strength capable of withstanding a predetermined vertical load by itself.

Images